Yieldable guide for a door

Information

  • Patent Grant
  • 6574832
  • Patent Number
    6,574,832
  • Date Filed
    Tuesday, May 30, 2000
    24 years ago
  • Date Issued
    Tuesday, June 10, 2003
    21 years ago
Abstract
A flexible guide for a door includes straps that are mounted in pairs along either side of a doorway. The straps for each pair are generally parallel, facing each other, and spaced apart to create a gap or channel between the two. As the door opens and closes, the straps guide the vertical movement of a door panel that travels within the channel. The straps are pulled in tension between upper and lower anchors to provide the straps with enough stiffness to effectively hold the door panel within the channel under normal operation. In some embodiments, springs are used to maintain the tension in the straps. The straps are also sufficiently pliable and resilient to allow an impact to dislodge the door panel out from within the channel without damage. The upper or lower anchor is moveable between a normally extended position and a yielded position to prevent an impact from breaking the anchor and may further be biased to the normal position.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The subject invention generally pertains to doors and more specifically to a door guide that provides a door panel with a breakaway feature.




2. Description of Related Art




Industrial doors are often comprised of a fabric curtain or have one or more panels whose vertical movement between an open and closed position is guided by tracks disposed along lateral edges of a doorway. Examples of such doors include, but are not limited to roll-up doors, concertina doors, planar doors and overhead-storing doors.




A roll-up door typically includes a pliable roll-up panel or curtain that is wound about an overhead roller. The curtain often includes several spaced-apart horizontal stays or wind bars that are relatively rigid to help prevent the curtain from billowing when subject to an air pressure differential across opposite faces of the curtain. To close the door, the roller pays out the curtain as two vertical tracks disposed along either side edge of the doorway guide the side edges of the roll-up panel generally along a vertical plane across the doorway. The rotation of the roller is reversed to open the door. Roll-up doors are typically either powered open and closed, or are powered open and allowed to fall closed by gravity.




A concertina door typically includes fabric curtain similar to a roll-up door with vertically spaced horizontal bars disposed thereon. To open and close the door, vertical straps are connected to a roll-tube above the doorway and are also connected to alternating bars disposed along the curtain. Winding up of the straps lifts the bottom bar, which also picks up the bars above, while the curtain fabric folds (concertina-style) between the accumulating bars. When fully open, the bars and folded-up curtain are aggregated above the doorway. Unwinding the straps reverses the process. As with a roll-up door, the vertical movement of the curtain and bars are guided by vertical tracks disposed along each side of the doorway.




A planar door includes a door panel that remains generally planar as the panel moves vertically between its open and closed positions. When open, the door panel stores generally adjacent a wall above the doorway with the plane of the panel being parallel or at a slight angle to the wall. Again, the vertical movement of the door panel is guided by vertical tracks disposed along each side of the doorway.




An overhead-storing door includes a series of panels that are pivotally interconnected at horizontal joints. As the door closes, vertical guides along the lateral edges of the doorway guide the panels to a vertical position. When the door opens, the pivotal joints allow the panels to store horizontally overhead, as in a conventional garage door.




Industrial doors, such as the ones just described, are commonly installed in warehouses where the doors are very susceptible to being struck by forklifts or other vehicles. To protect the door and the vehicle from damage, often some type of breakaway or compliant feature is added to the door, which allows the door to move into and out of the doorway in the event of an impact. Although there are a wide variety of breakaway devices available, perhaps the most economical is one where the vertical guide comprises a flexible strap that yields to release a struck door panel.




For example, a guidance device of the published international patent application WO98/48139 (Oct. 29, 1998) employs a fabric strap as a guide or track for the vertical movement of a door panel (i.e., a curtain with or without horizontal bars, a rigid single panel or panels, etc.). If the panel is struck, the flexibility of the strap allows the panel to break out from within the guide to prevent damaging the panel or the track. Although the guide is flexible for most of its length, its lower anchor is a fixed hexagonal post that protrudes several inches into the doorway. If a forklift or the load it is carrying were to hit the post, it could permanently bend or break off entirely. Thus, the protruding post provides a hard stop that can narrow the effective width of the doorway.




SUMMARY OF THE INVENTION




In order to provide a door with a breakaway feature, in one embodiment a door guide is provided with a yieldable strap that is disposed between two anchors, wherein at least one of the anchors is moveable from a normal position to a yielded position in response to an impact. The moveable anchor may be resiliently returnable to the normal position after the impact.




In some embodiments, the lower anchor is biased to its normal position.




In some embodiments, the lower anchor is biased to its normal position by way of a spring.




In some embodiments, the lower anchor is biased to its normal position by way of a torsion bar.




In some embodiments, the lower anchor is biased to its normal position by way of tension in the strap.




In some embodiments, the lower anchor is biased to its normal position by virtue of the lower anchor consisting of a resilient polymer.




In some embodiments, the strap is held in tension by a spring.




In some embodiments, a single strap is disposed along each lateral edge of the doorway, wherein each strap loops underneath a lower anchor to provide two generally parallel strap segments between which a door panel is guided.




In some embodiments, the guide strap is of a color recognized by OSHA (Occupational Safety and Health Administration of the U.S. Department of Labor) as a safety color (e.g., yellow, orange, or red) to serve as a safety warning that identifies the proximity of a hard edge of a doorway.




In some embodiments, the guide strap includes a reflective surface to provide a clearly visible indication of the proximity of a hard edge of a doorway.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a front view of a closed door that includes a flexible door guide.





FIG. 2

is the same as

FIG. 1

, but with the door partially open.





FIG. 3

is the same as

FIG. 1

, but with the door fully open.





FIG. 4

is a side view of a lower anchor used in the door of FIG.


1


.





FIG. 5

is a front view of FIG.


4


.





FIG. 6

is a front view of a spring-loaded upper anchor used in the door of FIG.


1


.





FIG. 7

is a side view of the upper anchors used in the door of FIG.


1


.





FIG. 8

is the same as

FIG. 4

, but with the lower anchor in a yielded position as opposed to a normal position.





FIG. 9

is the same as

FIG. 5

, but with the lower anchor in a yielded position as opposed to a normal position.





FIG. 10

is a cross-sectional view taken along line


10





10


of FIG.


11


.





FIG. 11

is a partial front view of another door that includes a guide strap and a spring to tighten the strap.





FIG. 12

is a partial front view similar to

FIG. 11

, but showing an alternate spring.





FIG. 13

is a top view of the lower anchor of the door shown in

FIG. 10

, but with the anchor in one of its yielded positions.





FIG. 14

is a cross-sectional top view taken along line


14





14


of

FIG. 10

, and is the same as

FIG. 13

but with the lower anchor in its normal position as opposed to its yielded position.





FIG. 15

is the same as

FIG. 13

, but with the lower anchor in another yielded position.





FIG. 16

is a top view of a polymeric lower anchor.





FIG. 17

is a front view of the anchor of FIG.


16


.





FIG. 18

is the same as

FIG. 16

, but with the anchor in a yielded position.





FIG. 19

is the same as

FIG. 17

, but with the anchor in the yielded position.





FIG. 20

is a top view of another polymeric lower anchor.





FIG. 21

is a front view of the anchor of FIG.


20


.





FIG. 22

is a front view of a cam-actuated lower anchor.





FIG. 23

is the same as

FIG. 22

, but with the anchor in a yielded position.





FIG. 24

is a front view of a spring-loaded, cam-actuated lower anchor.





FIG. 25

is a cross-sectional view of a yieldable anchor taken along line


25





25


of FIG.


26


.





FIG. 26

is a cross-sectional view taken along line


26





26


of FIG.


25


.





FIG. 27

is a cross-sectional view taken along line


27





27


of FIG.


25


.





FIG. 28

is a cross-sectional view taken along line


28





28


of FIG.


25


.





FIG. 29

is similar to

FIG. 25

, but with the anchor in a yielded position.





FIG. 30

is a cross-sectional view taken along line


30





30


of FIG.


31


.





FIG. 31

is a partial front view of another door that includes a relatively rigid side panel, such as a guide strap made of sheet metal.





FIG. 32

is a cross-sectional top view of the embodiment shown in

FIGS. 30 and 31

, but with the side panel in one of its yielded positions.





FIG. 33

is a cross-sectional top view taken along line


33





33


of

FIG. 30

, and is similar to

FIG. 32

, but with the side panel in its normal position as opposed to its yielded position.





FIG. 34

is similar to

FIG. 32

, but with the side panel in another yielded position.





FIG. 35

is a front view similar to

FIG. 22

, but with the anchor mounted to the backside of a side frame.





FIG. 36

is similar to

FIG. 36

, but with the anchor in a yielded position.





FIG. 37

is a cross-sectional view taken along line


37





37


of FIG.


36


.











DESCRIPTION OF THE PREFERRED EMBODIMENT




An industrial door


10


is shown closed, partially open and fully open in

FIGS. 1

,


2


and


3


, respectively. To open or close door


10


, a powered roller


12


draws in or pays out a roll-up door panel


14


that is wrapped around the roller. Panel


14


preferably comprises a flexible fabric, such as conventional PVC coated, polyester-base fabric reinforced with relatively rigid stays or wind bars


16


. Wind bars


16


are held in place by integral pockets that are sewn or heat welded to panel


16


. It will be appreciated by one of skill in the art that the inventive concepts disclosed herein are adaptable for use with other doors besides those comprised of windbar-reinforced fabric curtains.




To guide the panel's vertical movement across a doorway


18


, each side edge


20


of panel


14


travels within a gap


22


(

FIG. 4

) between a pair of parallel guide straps


24


. In this embodiment, guide straps


24


are held in tension along either lateral edge


26


of doorway


18


. As guide straps


24


may be adapted for use with roll-up doors, they will be described with reference thereto. However, guide straps


24


are readily suitable for other doors including, but not limited to, concertina doors, planar doors and overhead-storing doors. Those skilled in the art, however, should appreciate that the other doors may need some obvious modifications in order to employ a strap-style guide. For example, when straps are used in guiding the vertical movement of an overhead-storing door panel, the upper ends of the straps should obviously lead into a more rigid track that includes a horizontal section and a curved section that directs the door from its overhead horizontal position to its vertical position. Moreover, while the embodiments depicted in the drawings are mostly directed to straps


24


being normally held in tension, the invention may not be so limited. Rather, the inventive concepts described herein may be applied to straps that are normally un-tensioned and which go into tension upon an impact on the door or other force being applied to the straps.




Returning to the current embodiment, straps


24


are preferably made of a pliable fabric, such as nylon, that when held in tension, they have sufficient stiffness to guide the vertical movement of panel


14


, yet have the flexibility to release panel


14


out from within gap


22


when a certain breakaway force


26


(

FIG. 10

) is applied against panel


19


. To achieve the proper tension, strap


24


is stretched between an upper anchor


28


and a lower anchor


30


, both of which are attached to a sheet metal side frame


32


. Upper anchor


28


can be similar to the upper or lower anchors of earlier-mentioned WO98/48139, or spring-loaded as shown in

FIGS. 6 and 7

.




A spring-loaded anchor, upper or lower, can maintain sufficient tension in strap


24


even if the fabric tends to creep or stretch over time. A spring-loaded anchor can also keep a strap taut with use under varying conditions, such as varying temperature, humidity, and frequent panel/guide breakaways. In addition, spring-tensioning can add programmability to the breakaway. One of skill in the art will appreciate that both the “normal” tension in the strap (i.e., when no impact force is applied to the curtain) as well as the increase in tension in the strap resulting from impact can be set by selecting a given spring and/or pre-stressing of that spring. Different springs or pre-stressing will alter the response of the strap. Incidentally, alternative strap materials may alter this response as well.




Applying tension to strap


24


can be achieved in a number of ways. For example, referring to

FIG. 6

, upper anchor


28


includes a U-shaped bar


34


having two legs


36


that rotationally disposed about a shaft


38


. Shaft


38


rigidly extends from a support plate


40


that bolts or otherwise attaches firmly to side frame


32


. A shaft collar


42


with an axial hole


44


and a radial setscrew


46


grips shaft


38


to loosely hold bar


34


to shaft


38


in an axial direction. A torsion spring


48


having one end


50


engaging axial hole


44


and an opposite end


52


engaging one leg


36


of bar


34


allows bar


34


to be rotationally stressed relative to shaft


38


. To achieve the desired tension in strap


24


, bar


34


can be manually rotated a desired amount before one end of strap


24


is iniserted between bar


34


and shaft


38


, as shown in FIG.


7


. For illustrative purposes, only one of the two straps is shown in FIG.


7


. If desired, shafts


54


can be added to create a tapered lead-in


56


for panel


14


, to create a storage area for concertina-style panels, and/or to simply place the upper ends of straps


24


in their proper position. Shafts


54


can be mounted to side frame


32


by using a support plate


58


similar to plate


40


.




In some circumstances, a strap alone may allow a door panel to break away under impact; however, the flexibility of the strap may be restricted where the strap is anchored to the edge of the doorway. Thus, one or more of the anchors that support the strap are preferably provided with some ability to move or yield in response to an impact force applied against the door panel or to the strap guide or applied against the anchor itself. Preferably, such yieldability is accompanied by the ability of the anchor to be returned to its normal position, and structure for providing such restorative force. For example, a strap anchor could pivot about a vertical axis in response to an impact, and then spring force, tension in the strap, or some other restorative force could return the anchor back to its normal operating position. Such resilient anchors can be of a variety of designs and be mounted in various ways. They can be mounted near the bottom of the doorway and/or near the top. The anchors can have a point of attachment on the door side of side frame


32


or on the backside of side frame


32


.




To provide a lower anchor that resiliently yields when struck, in one embodiment a lower anchor


30


comprises two steel rods


60


and


60


′ that are a mirror image of each other, and each are formed to include a pivotal arm


62


and an integral torsion bar


64


. Several strap clamps


66


attach rods


60


and


60


′ to side frame


32


. Strap


24


includes a lower loop


68


that slips around arm


62


, while an offset end


70


of rods


60


and


60


′ help keep strap


24


from slipping back off. An upper horizontal segment


72


helps hold rods


60


and


60


′ at their proper height and also rotationally fixes the upper end of torsion bar


64


. Although the upper end of torsion bar


64


is fixed, strap clamps


66


have sufficient radial clearance to allow the remainder of torsion bar


64


to twist resiliently (i.e., elastic strain). The radial clearance can be achieved by having slightly oversized strap clamps, or by having clamps


66


tighten about a bushing that has a slip-fit clearance to rods


60


and


60


′. Torsion bar


64


being able to twist resiliently allows arm


62


to pivot when struck and then spring back to its original position after the striking force is removed. This action allows lower anchor


30


to be moveable from a normal position (FIGS.


4


and


5


), to a yielded position in response to an impact (FIGS.


8


and


9


), and then returnable back to its normal position. In one embodiment, torsion bar


64


is about 4-feet long with a 0.25-inch diameter, and pivotal arm


62


is about 4.5 inches long, and may be reinforced with an appropriate brace or gusset if desired. However, various other dimensions may be used depending on numerous factors including material properties, strap width, strap tension, and the desired spring-back of the pivotal arm.




Lower anchor


30


being moveable renders strap


24


yieldable down to its lowest point. Thus, strap


24


can serve as a yieldable standoff that may keep vehicles a safe distance away from an unyielding hard edge, such as edge


26


of doorway


18


. Toward that end, strap


24


may be provided in a safety color. Yellow, for example, is recognized by OSHA as a color to indicate the presence of a striking hazard. Other bright or fluorescent colors such as red and orange, or a reflective surface


74


, such as reflective tape, may also provide an effective visual warning.




In alternate embodiments, the tension in a guide strap


76


is provided by a tension spring


78


, as shown in

FIGS. 10 and 11

, and alternately provided by a compression spring


80


, as shown in FIG.


12


. In either case, strap


76


can be a single strap that loops underneath a lower anchor


82


to create two generally parallel strap segments


76




a


and


76




b


that are integral extensions of each other. Door panel


14


can then travel vertically along a gap


84


between strap segments


76




a


and


76




b.


One end of strap


76


includes a loop


86


held stationary by an upper anchor


88


, such as a shaft similar to shaft


54


. An opposite end of strap


76


includes a point


90


connected to one end of spring


78


, with an opposite end of spring


78


being connected to a stationary bracket


92


that is attached to side frame


32


. Thus, spring


78


pulling on point


90


creates tension in both strap segments


76




a


and


76




b.


This may advantageously allow strap


76


to be formed of a less resilient (and perhaps less expensive) material than in other embodiments, as the spring provides the resiliency.




To readily adjust the tension in strap


76


, refer to the embodiment of FIG.


12


. Here, an eyebolt


94


connects point


90


to a bracket


96


that is fixed to side frame


32


. Compression spring


80


pushes between bracket


96


and a nut


98


on eyebolt


94


to apply tension to strap


76


. Tightening or loosening nut


98


adjusts the tension in strap


76


.




Although springs


78


and


80


are readily adapted to various strap configurations (e.g., single or dual straps) and various lower anchors (e.g., single or dual arms), in one embodiment, lower anchor


82


includes a conventional double-acting spring hinge


100


that pivotally mounts a single arm


102


to side frame


32


. Hinge


100


inherently includes an internal torsion spring


104


disposed about each hinge pin


106


. Torsion springs


104


urge arm


102


to its normal position of

FIGS. 10

,


11


and


14


, but also allows arm


102


to move to yielded positions in either direction by pivoting about either hinge pin


106


, as shown in

FIGS. 13 and 15

. Although double-acting spring hinge


100


could be of any suitable size or make, in one embodiment, hinge


100


is identified as a catalog part number 1479A23 of McMaster-Carr of Chicago, Ill. Arm


102


, which extends from hinge


100


, has a U-shaped cross-section to provide a low cavity


108


into which a lower edge


110


of panel


14


may travel. The smooth U-shape underneath arm


102


also allows the tension in one strap segment


76




a


to be transferred to the other strap segment


76




b,


which allows the use of one spring


78


or


80


to tighten both strap segments.




Various other designs of an anchor that is moveable between a normal position and a yielded position are well within the scope of the invention. For example, a lower anchor


112


, of

FIGS. 16-19

, consists of a flexible polymer, such a polyurethane, polypropylene, rubber, etc. The shape of anchor


112


is such that it provides ample strength and rigidity in a vertical direction to maintain tension in a guide strap, yet is sufficiently thin horizontally to resiliently flex from a normal position (

FIGS. 16 and 17

) to a yielded position (

FIGS. 18 and 19

) and then return to its normal position. Lower anchor


112


could be used as a dual arm anchor, wherein separate straps are individually attached to arms


114


and


116


. The straps can be attached to arms


114


and


116


by any conventional fastener including, but not limited to, screws, hooks, rivets, and adhesive.





FIGS. 20 and 21

illustrate another anchor


118


that is similar to anchor


112


, but includes an integral bottom portion


120


, which allows a single strap to loop underneath anchor


118


without the strap pinching arms


114


and


116


together. Anchor


118


defines a cavity


122


that provides a function similar to that of cavity


108


of anchor


82


.





FIGS. 22 and 23

illustrate yet another embodiment of an anchor


124


. In this example, a vertical leg


126


of an L-shaped arm


128


is journalled within a fixed sleeve


130


having a beveled lower edge


132


, such that edge


132


serves as a cam surface that urges a horizontal leg


134


of arm


128


to its normal position (FIG.


22


). An external force or impact can move arm


128


to a yielded position (FIG.


23


); however, tension in guide strap


24


looped underneath leg


134


pulls leg


134


against beveled edge


132


to create a reaction force


136


between leg


134


and edge


132


. A horizontal component


138


of reaction force


136


is what urges anchor


124


to its normal position. If desired, reaction force


136


can be increased by adding a spring, such as a tension spring


140


, which pulls upward on L-shaped arm


128


. One of skill in the art will appreciate that cam surface


132


may not be required in this embodiment, assuming other structure is present to provide the restorative force to return anchor


124


to its normal position from the yielded position. Moreover, with lower anchor


124


(as well as other lower anchors already described) the magnitude of force


126


(

FIG. 10

) that is needed to dislodge edge


20


(

FIG. 1

) out from within gap


84


is higher when door panel


14


is at its closed position (

FIG. 1

) than when at its intermediate position (FIG.


2


), because of the proximity of edge


20


to the lower anchor. Having a door that is more difficult to forcibly break open when in its fully closed position may be desirable for security reasons in some applications.




In another embodiment, shown in

FIGS. 25-29

, an anchor


142


has an attachment point disposed on the backside of a side frame


32


′ and includes a compression spring


144


that urges anchor


142


to its normal, outwardly extended position. That is, in the normal position, the anchor


142


includes a centerline


162


. While the anchor is yieldable by rotation about a generally vertical axis (as in previous embodiments), this embodiment is characterized by the restorative force being applied longitudinally along centerline


162


. Anchor


142


includes a central shaft


146


having a shoulder


148


at one end


150


and a threaded portion


152


at an opposite end. A sleeve


154


slipped over shaft


146


includes external flats or an outer surface


156


that is knurled, roughened or otherwise suitable for gripping a strap


158


upon strap


158


being wrapped around sleeve


154


(FIG.


27


). A nut


160


tightened on shaft


146


clamps sleeve


154


between nut


160


and shoulder


148


. This helps prevent strap


158


from unwrapping off of sleeve


154


by preventing sleeve


154


from rotating relative to shaft


146


.




To help prevent shaft


146


from rotating about its longitudinal centerline


162


, shaft


146


is coupled to a linkage assembly


164


. Assembly


164


includes an elongated square bar


166


whose rotation is limited upon extending through a mating square hole


168


in side frame


32


′ (FIG.


28


). A short link


170


is pivotally pinned to bar


166


and shaft


146


by way of pins


172


and


174


respectively. Other structure for securing a strap to anchor


142


, and/or preventing rotation thereof could also be employed.




To urge anchor


142


to its normally extended position, of

FIGS. 25 and 26

, compression spring


144


urges bar


166


to the right, as viewed in the drawings. Spring


144


does this by pushing against the backside of side panel


32


′ and against a washer


176


that is fixed relative to bar


166


by way of a third pin


178


. Bar


166


being pushed to the right pulls shaft


146


firmly against side panel


32


′. The flat face of shaft end


150


being pressed against side frame


32


′ tends to keep shaft


146


generally perpendicular to side frame


32


′.




However, in response to an impact against the door, strap


158


or anchor


142


, vertically extending pins


172


and


174


allow shaft


146


to pivot about a vertical axis to various yielded positions, as indicated by phantom lines


180


and


182


. In moving to the position of

FIG. 29

, the pivotal movement of shaft


146


about a sliding point


184


pulls link


170


away from side panel


32


′. This forces pin


178


of bar


166


to further compress spring


144


between washer


176


and the backside of side panel


32


′. The further compression of spring


144


is what causes anchor


142


to return to its normally extended position after the impact.




According to an alternative embodiment, the “guide strap” need not be a strap at all, but rather could be formed of a rigid material such as metal. In such an instance, the rigid guide member would be yieldable in a similar manner to the yieldable strap anchors discussed herein-illustratively by rotation about a generally vertical axis. While two independently-movable rigid guide members could be provided, the embodiment of

FIGS. 30-34

shows the two guide members being unitary. That is, the vertical edges of door panel


14


each travels within a U-shaped channel


186


that includes at least one sheet metal side panel


188


. This embodiment is similar to that of

FIGS. 10-15

, with the primary difference being panel


188


instead of strap


76


being used for guiding door panel


14


. Double-acting spring hinge


100


pivotally connects channel


186


to side frame


32


. In response to an impact, channel


186


can pivot from its normal position of

FIG. 33

to either of its yielded positions of

FIGS. 32 and 34

. After channel


186


has yielded to an impact, torsion springs


104


of hinge


100


urges channel


186


back to its normally extended position. Members


189


and


190


serve as a lead-in for door panel


14


to enter channel


186


.




In another embodiment, similar to those of

FIGS. 22-24

, anchor


124


is attached to a backside


192


of a side frame


32


″ to minimize the gap between strap


24


and side frame


32


″, to create a cleaner appearance, and to minimize encroachment of anchor


124


into the door opening. To allow leg


134


a sufficient range of pivotal movement from its normal position of

FIG. 35

to a yielded position of

FIGS. 36 and 37

, side frame


32


″ includes a notched-out portion


194


that provides clearance for leg


134


.




Although the invention is described with reference to a preferred embodiment, it should be appreciated by those skilled in the art that various modifications are well within the scope of the invention. For example, the various lower anchors just described are readily adapted for use as single or dual-arm anchors, wherein a single strap loops underneath a single-arm anchor to create two parallel strap segments with a door panel gap therebetween (e.g., FIG.


10


), and a dual-arm anchor includes two discrete arms adapted to attach to two separate, parallel guide straps (e.g., FIG.


4


). In other words, installing two single-arm anchors side-by-side creates a dual-arm anchor, and eliminating half of a dual-arm anchor creates a single-arm anchor. Of course, some dimensional changes may be needed. Although the various resilient anchors for a strap are primarily described with reference to a lower anchor, the anchors can also be mounted near the top of the doorway. Also, for the various springs used to tighten a guide strap, a single spring can be used to tighten two parallel segments of a single long strap (e.g., FIG.


10


), or two springs can be used with one on either end of the strap (e.g.,

FIG. 7

when used with the lower anchor of FIG.


10


). Thus, various lower anchors and various strap-tensioning springs can be combined and interchanged to create numerous embodiments that are all well within the scope of the invention. Therefore, the scope of the invention is to be determined by reference to the claims that follow.



Claims
  • 1. A door guide for a door panel that, in a lowered position, is adjacent a side frame, the door guide comprising:a first anchor moveable from a normal position to a yielded position in response to an impact, the first anchor being mounted adjacent the side frame such that movement of the first anchor from the normal position creates a restorative force, where the first anchor is returnable to the normal position from the yielded position by the restorative force; a first strap mounted to the first anchor and extending between the first anchor and a second anchor adjacent the door panel to guide the door panel; and a second strap running substantially parallel to the first strap to define a gap through which the door panel is adapted to travel.
  • 2. The door guide of claim 1, wherein the second anchor is moveable from a second normal position to a second yielded position in response to the impact, and wherein the second anchor is mounted adjacent the side frame such that movement of the second anchor from the second normal position creates a second restorative force, where the second anchor is returnable to the second normal position from the second yielded position by the second restorative force.
  • 3. The door guide of claim 1, wherein at least one of the first strap and the second strap comprises a flexible fabric.
  • 4. The door guide of claim 1, wherein the first strap and the second strap are an integral extension of each other to comprise a unitary strap.
  • 5. The door guide of claim 1, wherein the first anchor is biased to the normal position.
  • 6. The door guide of claim 5, wherein the first anchor includes a torsion bar that biases the first anchor to the normal position.
  • 7. The door guide of claim 5, further comprising a spring that biases the first anchor to the normal position.
  • 8. The door guide of claim 7, wherein the spring is a torsion spring.
  • 9. The door guide of claim 7, wherein the spring is a compression spring.
  • 10. The door guide of claim 7, wherein the spring is an extension spring.
  • 11. The door guide of claim 1, wherein the first anchor at least partially comprises a flexible, resilient polymer that urges the first anchor to the normal position.
  • 12. The door guide of claim 1, further comprising a spring coupled to the first strap to place the first strap in tension.
  • 13. The door guide of claim 12, wherein the spring is a compression spring.
  • 14. The door guide of claim 12, wherein the spring is an extension spring.
  • 15. The door guide of claim 12, wherein the spring is a torsion spring.
  • 16. The door guide of claim 1, wherein the first strap is held in tension with a force that increases as the first anchor moves from the normal position to the yielded position, whereby the increased tension in the first strap urges the first anchor to the normal position.
  • 17. The door guide of claim 1, wherein the first anchor includes a pivotal arm and a cam surface, wherein the first strap engages the pivotal arm and the pivotal arm moves along the cam surface upon the first anchor moving between the normal position and the yielded position, and wherein the pivotal arm engaging the cam surface urges the first anchor to the normal position.
  • 18. The door guide of claim 1, wherein at least a portion of the first strap and at least a portion of the second strap are an OSHA safety color including at least one of yellow, orange and red.
  • 19. The door guide of claim 1, wherein at least one of the first strap and the second strap includes a reflective surface.
  • 20. A door guide for a door panel, comprising a side structure being pivotal about a substantially vertical axis between a normal position and a yielded position and having a hinge mechanism coupled to a side frame adjacent the door guide and coupled to the side structure for biasing the side structure to the normal position, wherein the side structure is adapted to guide the door panel when the side structure is in the normal position and at least partially releases the door panel when the side structure is in the yielded position.
  • 21. The door guide of claim 20, wherein the side structure has a vertical length and the side structure is pivotal about the substantially vertical axis along the entire vertical length.
  • 22. The door guide of claim 20, wherein the side structure is further pivotal to an opposite yielded position with the normal position being between the yielded position and the opposite yielded position.
  • 23. The door guide of claim 20, wherein the side structure comprises a first side panel and a second side panel positioned such that the first and second side panels define a channel for at least a portion of the door panel.
US Referenced Citations (5)
Number Name Date Kind
5482104 Lichy Jan 1996 A
5535805 Kellogg et al. Jul 1996 A
5638883 Schulte Jun 1997 A
5887385 Horner et al. Mar 1999 A
6053237 Bertilsson et al. Apr 2000 A
Foreign Referenced Citations (2)
Number Date Country
0 922 650 Dec 2000 EP
WO-9848139 Oct 1998 WO
Non-Patent Literature Citations (1)
Entry
International Search Report corresponding to International patent Application Ser. No. PCT/US 01/17276, dated Oct. 22, 2001, 7 pages.